Missile launcher



July 25, 1961 H. GOLDSMITH MISSILE LAUNCHER l2 Sheets-Sheet 1 Original Filed Feb. 28, 1950 INVENTOR HE R85 R T GOLDSMITH W ww- Q/B ATTORNEYS July 25, 1961 H. GOLDSMITH 2,993,412

MISSILE LAUNCHER Original Filed Febl. 28, 1950 12 Sheets-Sheet 2 1 mveu'ron T aowsmm JLQM QIBMWK ZES July 25, 1961 H. GOLDSMITH MISSILE LAUNCHER 12 Sheets-Sheet 3 Original Filed Feb. 28, 1950 l HE REE R T GOLDSMI TH FORWARD BY Q/3WW 12 Sheets-Sheet 4 ATTORNEYS H. GOLDSMITH MISSILE LAUNCHER July 25, 1961 Original Filed Feb. 28, 1950 HERBERT GOLDSMITH July 25, 1961 H. GOLDSMITH 2,993,412

MISSILE LAUNCHER 12 Sheets-Sheet 5 Original Filed Feb. 28, 1950 a; t INVENTOR HERBERT aowsmm BY glam ATfORNEYS July 25, 1961 H. GOLDSMITH MISSILE LAUNCHER Original Filed Feb. 28, 195 0 12 Sheets-Sheet 6 y 1961 H. GOLDSMITH 2,993,412

MISSILE LAUNCHER Original Filed. Feb. 28, 1950 12 Sheets-Sheet 7 FIG.

l J Ill",

FIG'. 12

INVENTOR HEPBER T GOLDSMITH .4 (am BY mums July 25, 1961 H. GOLDSMITH MISSILE LAUNCHER 12 Sheets-Sheet 8 Original Filed Feb" 28, 1950 llllllIIllIIIllIIIIIIIIIII IIIIIIIII'" INVENTOR HERBERT aowsm 7/! BY x FIG. 14

ATTORNEYS H. GOLDSMITH MISSILE LAUNCHER 12 Sheets-Sheet 9 July 25, 1961 Original Filed Feb. 28, 1950 186R --I6I FIG. [6

INVENTOR HERBERT 601. 03?! BY I July 25, 1961 H. GOLDSMITH 2,993,412

MISSILE LAUNCHER Original Filed Feb. 28, 1950 12 Sheets-Sheet ll mven'roa HERBER T 601. DSM/Tl'l BY QUE/'3;

ATTORNEYS United States Patent 4 Claims. (Cl. 891.7) (Granted under Title 35, US. Code (1952), see. 266) The present invention is an improvement in missile launchers, and more particularly relates to rocket launchers and automatic feeds therefor, whereby rockets or other missiles may automatically be fed and fired at a predetermined rate, or fed and fired singly, as determined by the operator. This application is a division of my copending application Serial No. 146,891, filed February 28, 1950 for Missile Launcher, now US. Patent 2,973,691.

With the increased importance of rockets in naval and military operations, it becomes important to provide a means for automatically firing rockets akin to machine gun and other automatic weapon operation. To this end the present device is provided, essentially, with means for automatically and continuously feeding rockets or other missiles to and loading them into a launching barrel and firing them at a predetermined rate, or firing them singly, as determined by the operator. Under automatic feed and fire, as the feeding and loading mechanisms deliver each rocket to and position it in the launching barrel, the rocket is automatically fired and the barrel prepared for receiving the next rocket as fed thereto and loaded therein by the mechanisms, or under single feed and fire, the operator fires a single rocket as desired and then operates a control means causing another rocket to be fed into the barrel. In addition, the present rocket launcher is provided with means for automatically stopping the automatic feeding and loading of rockets into the launching barrel upon the failure of a rocket positioned therein to fire within a predetermined time, and is further provided with jettisoning means for ejecting such a dud rocket from the launching barrel in order that the mechanism may resume its normal operation.

Although developed primarily for the purpose of launching rockets and although herein described principally in its embodiment as a rocket launcher, many features of the present invention are equally applicable to other embodiments and uses, and it is not intended to limit the scope of the present invention to a rocket or missile launcher.

It is, therefore, one object of the present invention to provide a feeding or conveying mechanism operating in synchronous conjunction with an impelling mechanism to continuously feed objects such as rockets, at a determined and constant rate to the impelling mechanism, which latter mechanism operates to accelerate or impel the objects thus fed thereto; and if desired, a gated receptacle may be provided for receiving said objects, opening and closing in synchronism with the accelerating operation.

It is another object of the present invention to provide for automatic feeding of missiles to, loading them into, and firing them from a launching barrel, the rate of automatic operation being variable as desired.

Another object of this invention is to provide a feeding "ice or conveying mechanism suitable for feeding missiles to a launching barrel at a continuous rate, thereby eliminating shocks and strains to the supporting structure which result from intermittent feeding.

Another object of this invention is to provide a loading means, for accelerating the movement of missiles or other objects fed thereto by the feeding mechanism to insure their proper entry and positioning in a launching barrel or other receptacle, and for opening and closing a launching barrel or other receptacle loading gate in synchronism with the impelling of objects thereto by the loading mechanism, to present an open gate for an object as it is fed thereto and to close said gate after loading.

Another object of the present invention is to provide such a missile launcher with means for deflecting exhaust blast gases and preventing their deleterious leakage from the launching barrel to protect the launcher structure and the operator.

A further object of the present invention is to provide a buffer mounting for the receptacle or missile launching barrel, thereby reducing shocks on the structural supporting frame which would otherwise be imposed by the accelerated movement of a missile or other object being positioned therein.

Another object of the present invention is to provide a complete mechanical interlock of operation between the feeding or conveying and loading mechanisms so that synchronous operation thereof is not alfected by maneuvering accelerations of the craft on which the device is mounted. This mechanical interlock is of particular significance when the present device is mounted on aircraft.

Another object of the present invention is to provide for control of the rate of automatic operation of the feeding, loading, and firing mechanisms. The complete interlock of all moving parts enables this control to be established in a single means, namely in the power drive source.

Another object of the present invention is to provide for positively maintaining the missiles or other objects in proper position within the feeding or conveying mechanism magazine and Within the receptacle or launching barrel despite acceleration loads that may be imposed thereon due to maneuverings of the craft carrying the present device.

An additional object of the present invention is to provide an electrical firing and operational control system for firing missiles properly positioned in the launching barrel and for controlling the operation of the feeding, loading, and jettisoning mechanisms, the firing circuit thereof being in turn controlled by the loading mechanism to prevent premature firing of a missile before closure of the launching barrel.

Another object of the present invention is to provide for automatically interrupting the operational control circuit to prevent continued feeding of missiles to the loading mechanism when a missile positioned in the launching barrel fails to fire during a predetermined portion of the operational cycle of the present device.

Another object of the present invention is to provide for the jettisoning from the launching barrel of dud missiles, or missiles which have failed to fire within the above-mentioned predetermined portion of the operational cycle, in order that the operation of the present device may be resumed.

An additional object of the present invention is to provide for automatic breaking of the electrical firing circuit during the jettisoning operation to prevent energization thereof during this operation, thereby insuring against the accidental firing of a missile as it is being jettisoned from the launching barrel.

A further object of the present invention is to provide for automatic zeroing of the feeding and loading mechanisms, so that up on deenergization of the firing circuit, the operational control circuit remains energized to continue the feeding and loading of missiles into the launching barrel until a missile has been positioned within said tube and said tube is in readiness for fire, thereby enabling the present mechanism to be in readiness for instantaneous fire.

A further object of the present invention is to provide for both single and automatic feed of objects and single and automatic feed and fire in the case of rockets or other missiles, as desired by the operator.

A still further object of the present invention is to provide means for facilitating the positioning of missiles or other objects in the magazine and insuring against the accidental firing of a missile or the like while such objects are being positioned therein.

In general, the present invention is designed to accomplish the foregoing objects, and in the automatic feed and fire aspect thereof comprises an automatic feeding mechanism, a launching barrel, an automatic loading mechanism, a jettisoning means, a power source for motivating both the feeding and loading mechanisms, the latter two mechanisms being mechanically interlocked for synchronous operation, and an electrical firing and operational control system for firing a rocket positioned within the launching barrel and for controlling the operation of the feeding, loading, and jettisoning means. The feeding mechanism comprises a magazine or rack wherein a plurality of missiles or other objects are positioned and engaged by a plurality of star wheels. Rotation of the star wheels causes movement of the objects along the magazine toward the delivery end of the magazine, the projections of said star wheels causing and controlling the movement of the objects. The star wheels are all actuated by a single power source, and their movement is maintained in synchronism by suitable means such as a chain and sprocket drive. The launching barrel comprises an inner guide tube and an outer gate tube mounted for relative rotation at the delivery end of the feeding mechanism magazine, into which the missiles are positioned by the loading mechanism, and from which they are launched upon being fired by the firing circuit. The guide tube is designed to substantially enclose a missile positioned therein except for an elongated opening forming a loading gate which in the normal operation of the present rocket launcher is directed toward the delivery end of the feeding mechanism and through which the missiles are loaded into the tube. The loading mechanism comprises essentially two portions: one being an acceleration portion for accelerating the movement of the last missile being fed by the magazine in order to insure the entry thereof into the guide tube and its proper positioning therein; the other being a gate tube actuating portion, operating in synchronism with the acceleration portion for closing the afore-mentioned elongated opening or loading gate in the guide tube after a missile has been positioned therein and before it has been fired or launched therefrom, and for opening the same after a missile positioned in said guide tube has been fired to permit the entry of another missile as it is directed thereto by the acceleration portion of the loading mechanism. The acceleration portion comprises the last star wheels at the delivery end of the magazine, which are mounted thereon for rotational movement, as controlled by the afore-mentioned chain drive, and for reciprocatory motion therealong in synchronism with the operation of the gate tube portion, thereby imparting an accelerated movement to the missiles as they reach the delivery end of the magazine to insure their proper entry into the guide tube. The gate tube portion comprises a tube mounted on and rotatable about the guide tube, likewise having an elongated opening therein substantially the same size as that in the guide tube. The synchronous operation between the gate tube and the accelerating mechanism is such that upon the firing of a missile positioned in the guide tube and as another missile is accelerated from the magazine thereto, the opening in the gate tube is brought into coincidence with the corresponding opening in the guide tube by rotation of the former about the latter to present an open loading gate; and upon completion of the loading operation, the gate tube is again rotated to bring its opening out of coincidence with that in the guide tube to close the loading gate, thereby forming a complete enclosure for the missile before it is fired. The power source for the mechanical operations of the feeding and loading mechanisms comprises any suitable variable speed motor which operates upon these mechanically interlocked mechanisms to drive them at synchronized rates of operation, as determined by the characteristics of the interlock therebetween. The jettisoning means comprises a rack and gear arrangement operating to rotate the guide tube. If a dud missile is positioned in the launching barrel and it is desired to eject the same therefrom in order that operation of the device may be resumed, energization of the jettisoning means causes a rotation of the guide tube to bring the gate opening therein into registry with the corresponding opening in the gate tube, the gate tube being then positioned to close the loading gate with its opening directed away from the feeding magazine, thereby enabling the ejection of the dud missile through the registered openings. The electrical firing and operational control system operates through its operational control circuit simultaneously upon a clutch and a brake on the drive shaft for the feeding and loading mechanisms to initiate and to continue or to stop the operation thereof, and while operating the same to automatically fire the missiles through its firing circuit as they are positioned within the guide tube and after the loading gate is closed. If during operation of the present device a dud missile is positioned within the barrel, an automatic cutoff operates upon the operational control circuit to cause the feeding and loading mechanisms to cease operation until the dud missile has been jettisoned and the guide tube returned to its normal operating position.

In the nonautomatic or single feed and fire aspect of the present invention, the sole change in design resides in the electrical firing and operational control circuit, otherwise the device being the same in its structure and function as above described for the automatic feed and fire aspect. To effectuate the nonautomatic operation, the electrical firing and operational control circuits are independently energized. Thus, a missile positioned within the launching barrel is fired without initiating the feeding and loading mechanisms, and when the launching barrel is empty the operational control circuit is energized to feed a single missile into the launching barrel while the firing circuit remains inactive, thereby preventing the firing of the missile until desired and thus obtaining a single cycle operation of the present missile launcher and its associated feeding and loading mechanisms.

A full understanding of the present invention can be best had by a consideration of the following detailed description thereof, directed by way of example to an embodiment suitable for launching rockets, and made in conjunction with the accompanying drawings in which like numerals refer to similar or corresponding parts and wherein;

FIG. 1 is a bottom plan view of a rocket launcher embodying the present invention, a portion being broken away;

FIG. 2 is a top view of the power drive system for the feeding and loading mechanisms, these mechanisms having been removed to reveal the system;

FIG. 2a is an end view of a flexible coupling taken along line 2a-2a of FIG. 2;

FIG. 2b is a vertical sectional view of the flexible coupling taken along line 2b-2b of FIG. 2a;

FIG. 3 is a bottom plan view taken from below the rocket launcher showing the rocket magazine, the rockets loaded therein, and the guide and gate tubes;

FIG. 4 is a transverse section through the rocket launcher taken along a line substantially corresponding to line 4-4 of FIG. 1;

FIG. 5 is a smaller view taken along a line substantially corresponding to line 5-5 of FIG. 1;

FIG. 6 is a longitudinal section through the feeding mechanism portion of the launcher and taken along a line substantially corresponding to line 6-6 of FIG. 3;

FIGS. 7, 8, and 9 are vertical cross-sectional schematic views of the guide and gate tube in their several posi tions, loading, firing, and jettisoning respectively;

FIG. 10 is an enlarged detailed horizontal longitudinal section of the rear or exhaust end of the guide and gate tubes and their mounting structure;

FIG. 11 is a vertical cross section through the guide and gate tubes in loading position and taken along a line substantially corresponding to line 11-11 of FIG. 10;

FIG. 12 is a vertical section of a safety latch taken along a line substantially corresponding to line 12-12 of FIG. 1;

FIG. 13 is a vertical cross-sectional view of the guide and gate tubes and mounting therefor taken along a line substantially corresponding to line 13-13 of FIG. 10;

FIG. 14 is a vertical section of the buffer mechanism taken along a line substantially corresponding to line 14-14 of FIG. 10;

FIG. 15 is a horizontal cross-sectional view of one of butter mechanisms taken along the line 15-15 of FIG. 13

FIG. 16 is a end view partially in section showing the guide tube and the jettisoning mechanism and taken along a line substantially corresponding to line 16-16 of FIG. 2;

FIGS. 17 and 18 are longitudinal sections of the jettisoning cylinder, showing it in two operative positions;

FIG. 19 is a schematic view of the hydraulic system of the present invention;

FIG. 20 is a schematic wiring diagram of the electrical firing and operational control system with the guide and gate tubes in loaded position ready to fire;

FIG. 21 is a view of a portion of FIG. 20 showing the guide and gate tubes in loading position;

FIG. 22 is similar to FIG. 21 but shows the tubes in jettisoning position; and

FIG. 23 is a cycle timing chart showing the time relationships of the various parts during a complete cycle of operation of the present invention.

Feeding and loading systems The rocket magazine of the present rocket launcher, in the embodiment shown in the accompanying drawings, comprises a lattice frame of structural beams indicated by the numerals 30, 30a, 30b, and 300. Referring particularly to FIGS. 3 and 6, a plurality of rockets 50 are positioned within the magazine defined by the abovementioned structure and, as mentioned above, are caused during the operation of the launcher to be advanced along the magazine toward the guide tube 101, into which they are fed by the loading mechanism, and from which they are fired. In order to guide the rockets in their movement along the magazine, two of the bottom beams 30a and 30b are provided with rails, beam 30a carrying the rail 56 upon which the forward ends of the rockets bear in their movement along the magazine, and beam 30b carrying the rail 54 which engages the rear ends of the rockets. The bases of the various rockets are 6 each provided with the circumferential grooves 53 designed to engage the rail 54. Rails 54 and 56 are positioned along the face of the magazine which would normally be the bottom thereof, while opposite therefrom on the top face of the magazine are the rails 56a and 54a carried by two of the beams indicated by the numeral 300 cooperating with the rails 56 and 54 respectively, rail 54a like 54 engaging the circumferential grooves 53 of the rockets, thus holding a rocket positioned within the magazine against longitudinal movement.

The feeding mechanism is mounted within the maga zine and serves to advance the rockets in unison toward the launching barrel. In the embodiment shown, the feeding mechanism comprises four substantially identical rocket advancing systems indicated generally in FIGS. 1 and 6 by the numerals 60, 61, 62, and 63, two being located adjacent the heads of the rockets and two being located adjacent the bases of the rockets. Each rocket advancing system comprises an endless chain drive 45 (FIGS. 4 and 5) supported between idler sprockets 46 at one side of the rocket launcher and idler sprockets 58 at the other side thereof and driven by the drive sprockets 58a (FIG. 1). The lower portion of these chains 45 engage and rotate a plurality of star wheel sprockets 47, each of which is carried by its respective stub shaft 48, while the chains are kept in full engagement with the teeth of the several sprockets by means of the guide blocks 52, one for each sprocket. A star wheel 35 is mounted upon each stub shaft 48 for rotation therewith. All the star wheels 35 impelled by a particular chain drive 45 are thus maintained in synchronous angular position and rotational movement, rotation thereof causing the rockets 50 to advance along the magazine, as impelled by the projections of the star wheels, toward the launcher barrel generally denoted by the numeral 100. All of the drive sprockets 58a are driven by a main drive shaft 465, rotation of which results in identical movement of the various chain drives 45 and of all the star wheels 35, thereby insuring the desired and proper advance of all the rockets in the magazine as controlled by the various star wheels. Thus in the operation of the feeding mechanism, rotation of shaft 465 impels in identical movement the several endless chain drives 45 to rotate the star wheels 35 through drive sprockets 58a, advancing all the rockets in the magazine in unison toward the launching barrel 100.

As mentioned in the introduction, the loading system has two portions, the feed accelerating portion, whereby the feed of the rocket closest to the launching barrel is accelerated over the feed of the remainder of the rockets and the loading gate portion, by means of which a guide tube gate is rapidly opened and closed in timed relation to the accelerated feed. Considering first the accelerating portion, and referring particularly to FIGS. 1 and 5, it includes the last star wheel 35a of each of the four rocket advancing systems and the sprockets and shafts associated therewith, as in the case of each of the other star wheels 35, and further includes the two substantially U-shaped yokes 31 upon which the star wheels 35a are rotatably mounted. These U-shaped yokes are slidably mounted for reciprocatory movement in any suitable manner, as for example by the bearing blocks 32. Each of said yokes 31 is linked to a separate bell crank 42, only one of which is shown in FIG. 5, by linkage elements 37 and 38, and each bell crank is controlled by its pair of operating cams 40 and 41. The cams 40 and 41 are keyed to the drive shaft 51, and as it rotates it simultaneously drives these cams whose surfaces bear against the bearing Wheels 43 and 44 rotatably mounted on the bell cranks 42. Rotation of the cams 40 and 41 results in an oscillatory movement of the bell cranks 42 which in turn, through the linkage element 37 and 38, drive the two yokes 31 in synchronous reciprocation along the blocks 32.

Since the last star wheels 35a of each rocket advancing system and their associated stug shafts and sprockets are mounted on the yokes 31 for reciprocation therewith, as the rotation of cams 40 and 41 causes a movement of yokes 31 to the left from the position as shown in FIG. 5, the movement of the star wheels 35a mounted thereon and their associated shafts and sprockets is in the opposite direction from the operating travel of the chain drive, therefore resulting in an increased rotational velocity of these star wheels, and causing an acceleration of the rate of movement of the last rocket in the magazine, under the control of these star wheels, as it is fed toward the launching barrel 100. Thus, as shaft 51 is caused to undergo one complete revolution, the yokes 31 undergo in unison one complete reciprocatory cycle, resulting in an acceleration of the feeding rate of the last rocket appreaching the launcher 100 through the accelerated rotational velocity of the star wheels 35a, to impel the rocket into the launching barrel and then a return of these last star wheels 35a to their starting position to receive the next rocket fed thereto to similarly impel the same into the launching barrel, the first mentioned rocket positioned therein having in the meanwhile been fired, as will be described in detail below.

Considering the combined operation of the feeding mechanism and the acceleration portion of the loading mechanism, rotation of shaft 465 causes a uniform advance of all the rockets in the magazine at a constant rate as controlled by the rotation of the star wheels 35, while the rotation of shaft 51 rotates the cams 40 and 41 and results in a reciprocatory movement of the group of last star wheels 35a to impel each rocket fed thereto by the preceding star wheels 35 into the launching barrel 100. As each rocket is being impelled into the launching barrel, the preceding star wheels 35 continue the uniform advance of all the following rockets in the magazine. Thus, the combination of the presently described acceleration portion of the loading mechanism and the feeding mechanism results in a continuous feed of rockets to the launching barrel 100 at a uniform rate except for the final accelerated impetus imparted to each rocket as it is loaded into the launching barrel, thereby minimizing and substantially eliminating the stresses and strains that would be imparted to the entire rocket launching mechanism and the supporting structure therefore as a result of an intermittent feed of rockets.

Considering, next, the gate portion of the loading mechanism, and referring particularly to FIG. 4, the launching barrel 100 comprises an inner guide tube 101, having an elongated opening 101a therein of sutficient size to permit the passage of a rocket therethrough, and a gate tube 102 rotatable about tube 101, the gate tube having an opening 102a therein corresponding in size to the opening 101a and an arcuate gear section 104 extending over a portion of the circumference thereof. This gate portion also includes the cams 111 and 112 keyed to the shaft 51, the bell crank 109 pivotable about the shaft 110 and having the bearing rollers 113 and 114 mounted thereon for engagement with the surfaces of cams 111 and 112 respectively, and a suitable rack and gear arrangement at 105 connected to the bell crank 109 by the linkages 107 and 108 and cooperating with the gear sector 104 to rotate the outer gate tube 102 about the inner guide tube 101 as controlled by the cams 111 and 112. The shaft 51 drives both the pair of cams 40 and 41, which controls the acceleration portion of the loading mechanism, and the pair of cams 111 and 112, which controls the gate portion thereof. Thus, with these two pairs of cams properly keyed to the shaft 51, the gate tube 102 is operated in synchronism with the operation of the last star wheels 35a. The cams 111 and 112 oscillate the bell crank 109 causing the gate tube 102, through the gear sector 104 and the rack and gear arrangement 105, to rotate about the guide tube 101 and alternately to bring the two openings therein into and out of registry. When the two openings are in registry and in alignment with the magazine, the launching barrel is ready to receive a rocket, and upon the loading of a rocket the guide tube remains stationary while the gate tube 102 is rotated to bring its opening out of registry with that in the guide tube, thereby forming a complete enclosure for the rocket positioned within the launching barrel and it is then in readiness for firing. After a rocket thus loaded has been fired, the gate tube 102 is rotated to again bring the openings in the two tubes 101 and 102 into registry and the operation is repeated. This entire cycle of operation of the gate tube is controlled by the cams 111 and 112 operating upon bell crank 109 and is accomplished during one complete revolution of the shaft 51. Thus, as the rockets are fed at a steady rate along the magazine under control of the star wheels 35, as driven by the shaft 465, the acceleration portion of the loading mechanism is operated by the earns 40 and 41 as impelled by the shaft 51 to apply an acceleration impetus to the last rocket as fed by the star wheels 35 to the group of last star wheels 35a. synchronously with the acceleration impetus, the cams 111 and 112 likewise impelled by the shaft 51 operate through hell crank 109 to bring the openings in the tubes 101 and 102 into registry, registry between the two openings being obtained as the rocket being delivered under the control of the star wheels 35a is being accelerated and impelled into the guide tube 101, and upon being positioned therein said openings are moved out of registry to completely enclose the rocket before it is fired.

Through the positive mechanical interlock arrangement above-described, the feeding and loading mechanisms are operated in synchronism despite loads that may be imposed by the maneuverings of the craft upon which the present launcher is positioned, this being of particular importance when the present rocket launcher is mounted upon an aircraft because of the particularly great inertia forces that may result from the maneuvering of such craft. To more fully understand this interlock, the power drive system of the above-considered structures will be here considered in detail with particular reference to FIGS. 2, 2a, and 2b. As will be considered in detail in the section entitled Hydraulic System, a hydraulic motor 425 operates through the gear box 466 to rotate oppositely extending shafts 467 and 468. Shaft 468 is connected to the gear box 471, through which it drives shaft 465 by means of a suitable gear arrangement, such as a worm gear. Shaft 465 is the star wheel drive shaft and rotates the feeding mechanism, as discussed in detail above. The other shaft 467 driven by motor 425 through the gear box 466 is connected to the gear box 469 through which it drives the shaft 470 by means of a suitable gear arrangement, such as a worm gear, shaft 470 being in turn connected to shaft 51 through the flexible coupling 483. Shaft 51 is the cam drive shaft which controls the operation of the loading mechanisms, as discussed in detail above. Thus, the two shafts 465 and 51, driving respectively the feeding and loading mechanisms, are driven by a single power source, namely the hydraulic motor 425, and are driven at a predetermined ratio of speed with respect to each other as controlled by the gear boxes 466, 471, and 469, thereby attaining a positive ratio of rotation between the shafts 51 and '465 through the mechanical shaft and gear interlock here described.

The flexible coupling 483, mentioned in the preceding paragraph as joining shafts 470 and 51, is shown in detail in FIGS. 2a and 2b and is formed of two sides, one side comprising the two elements 475 and 485 secured to shaft 470, the other side comprising the element 480 secured to shaft 51. The shaft 470 is keyed to the conical coupling element 475 through key 482 and keyway 481, while shaft 51 is keyed in a similar manner to the coupling element 480. The internal conical coupling 475 is fitted into the external conical coupling 485, thus juxtaposing their conical surfaces. Positive gripping engagement between the two surfaces is maintained by the internally threaded locking ring 476 carried by an externally threaded shoulder of the coupling element 475, which is held in clamping position by a set screw 477 carried by the coupling member 485 and engaging one of recesses 486 in the ring '476. The usual rubber or other resilient cushioning element 479 carried between two extending lugs 478 on element 485 and the two corresponding lugs 478a on coupling element 480 provides a cushioned drive connection between the coupled parts.

In order to establish the desired relation between the feeding and loading cycles, it is necessary that the angular adjustment of shaft 51 be at a specific relative position with respect to shaft 465. The flexible coupling 483 permits adjustment between shafts 51 and 470 in order to provide the desired relative angular position as be tween the shafts 51 and 465, which adjustment is attained by removing the set screw 477 and loosening the locking ring 476, thereby permitting loosening of the conical bearing surfaces between coupling elements 475 and 485. This being done, shaft 51 may be rotated with respect to shaft 470 until the desired relative angular position or cyclic position between shafts 51 and 465 is attained. Once this adjustment is made, the shafts 470 and 51 are then coupled to prevent relative rotation therebetween by tightening the ring 476 on the threaded portion of the coupling element 475, thus bringing the conical surfaces of coupling elements 475 and 485 into frictional engagement, and then inserting the set screw 477 into the coupling member 485 to prevent rotation and loosening of the ring 476. Operation of hydraulic motor 425 then impels the drive shafts 51 and 465 at a predetermined relative speed of rotation through the mechanical interlock described above, thereby effecting the desired synchronized operation of the feeding and loading mechanisms of the rocket launcher.

To prevent a rocket loaded in the launching barrel from bouncing back out through the loading opening before it is closed, as might result from the acceleration impetus applied to said rocket or from maneuverings of an aircraft upon which the launcher may be positioned, there is provided a rocket retaining arm generally indicated by the numeral 125, which is shown in situ in FIG. 1 located adjacent the launching barrel 100 and between the rocket advancing systems 61 and 62. As shown in FIG. 12, the rocket retaining arm comprises a bracket 133 secured to the undersurface of the upper structural frame of the magazine, a rod 126 reciprocable in said bracket and having a threaded extension 13 4 at one end and a pin 129 extending transversely through a narrowed portion 136 formed at its other end, an elbow arm 132 pivotally mounted on the bracket by pin 131 and having its short end bifurcated to embrace the nar row portion 136, the pin 129 being slideable in an elongated slot 135 formed in the bifurcated portion, a helical spring 127 encompassing a portion of the rod 126 and enclosed between the two washers 128 and 139 riding on rod 126, a spring tension adjustment sleeve 137 threaded onto the threaded rod extension 134, a lock nut 134a carried by the threaded extension 134 for securing sleeve 137 in adjusted position, and a threaded bushing 138 carried by the bracket 133 for slidably carrying the spring adjustment sleeve 137. In operation, as a rocket 50 is fed into the launcher 100 it passes under the elbow arm 132, from right to left as shown in FIG. 12, forcing it upwardly and causing it to pivot about its pivot point 131, resulting through its connection to the rod 126 in a movement of the rod from left to right in the view shown in FIG. 12. This movement of rod 126 causes a corresponding movement of sleeve 137 against washer 128 resulting in a compression of the helical spring 127. When the rocket 50 has entered the launching barrel 100 and clears the end of arm 132, the compressed spring 127 by the pressure exerted on washer 128 forces the sleeve 137, rod 126, and arm 132 to their starting positions, as shown in FIG. 12, to effectively prevent return of the rocket from the launching barrel before the loading gate has been closed. A stop 130 on the bracket 133 limits the return stroke of rod 126 to insure proper positioning of arm 132 when at rest.

Launching and jettisoning mechanisms The launching mechanism of the present device operates in conjunction with the above-described feeding and loading mechanism. The launching barrel indicated generally by the numeral essentially comprises two tubes, one within the other, the inner guide tube 101 having the rocket hearing or guide strips 103 extending substantially the length thereof and the rear step 103:: afiixed to the exhaust end thereof, and the outer gate tube 102 circumscribing tube 101. Generally, in the operation of loading and firing a rocket the launching barrel operates in the following manner, as illustrated in FIGS. 7 and 8; as the loading mechanism accelerates a rocket and impells it into the barrel 100, the guide tube 101 and the gate tube 102 are in the position shown in FIG. 7, that is, the openings 101a and 102a of the two tubes are in registry and directed toward the rocket magazine forming a rocket admitting opening; after the loading mechanism has impelled a rocket into position in the guide tube, the gate tube 102 rotates about the guide tube 101 into the position shown in FIG. 8, so as to close the rocket admitting opening and thereby provide an enclosed launching barrel. FIG. 9. shows the jettisoning position of the launching mechanism which may be attained when a rocket positioned in the guide tube fails to fire within a predetermined time. This position is reached by rotation of the guide tube 101 within the gate tube 102, the opening in the gate tube being then directed away from the rocket magazine, so as to bring the openings thereof into registry and enable the jettisoning of the rocket loaded in the launching barrel.

Referring now to FIG. 4, the operating mechanism of the launching barrel will be described. The guide tube 101 is shown with its opening directed toward the magazine or feeding mechanism, its normal operating position. Gate tube 102 is shown with its opening partly in registery with that of the guide tube, and it is provided with an arcuate gear segment 104 extending over a portion of its circumference to facilitate rotation thereof about the launching tube 101. Numeral 105 designates a suitable rack and gear box which cooperates with the gear segment 10 4 to control the rotation of tube 102 about the guide tube 101. As described in detail in discussing the loading mechanism, it is apparent that the operation of the gate tube 102 about the launching tube 101 must be synchronized with the feeding mechanism and acceleration portion of the loading mechanism in order that the openings in tubes 101 and 102 may be in registry and directed toward the feeding mechanism in readiness to receive a rocket to be fired coincidentally with the feeding thereof by the accelerating portion of the loading mechanism; and in addition, the movement of the gate tube 102 must be further synchronized therewith so as to close the rocket receiving gateway in order to permit firing of the rocket, and then to return to the open position as the next rocket is being impelled into the guide tube 101. This synchronous relationship is attained through the cams 111 and 112 as described in detail above.

Considering next the jettisoning mechanism of the launcher, its jettisoning position is shown in FIG. 9, where the gateway is formed by appropriate rotation of the tubes 101 and 102 so as to open in a direction away from the feedeing mechanism, which position may be obtained when a dud rocket has failed to fire within a predetermined time in order that it may drop or be ejected from the barrel. The jettisoning operation is performed by rotation of the guide tube 101, after the gate tube 102 has been rotated to close the gateway with a rocket loaded in the launching tube, so as to bring the opening 101a of tube 101 into coincidence with the then existing position of the opening 102a in tube 102. Referring now particularly to FIG. 16, this rotation of the guide tube 101 is accomplished in a manner akin to the rotation of the gate tube 102. The guide tube 101 has at one end thereof an arcuate gear segment 150 over a portion of its circumference, similar to the gear segment 104 on the gate tube 102, operating in conjunction with the gear box 156. Thus rotation of the gear 155 causes the desired rotation of the guide tube 101. The operation of the gear box 156 is controlled by a hydraulic piston, this control means being generally indicated by the numeral 157, which is shown in detail in FIGS. 17 and 18 and which is to be more fully described below.

The extent of a reciprocatory stroke of the hydraulic piston and the consequent stroke of the rack 151 which is operated thereby is controlled by the limit switch 161 having a depending switch arm 162. As the piston reciprocates, it engages the switch arm 162 at one end of its reciprocatory stroke by means of the adjustable limit pin 163, thereby throwing the switch, which through means hereinafter described causes the piston to move in the opposite direction until the arm 162 is engaged by the other adjustable limit pin 164, thereby throwing the switch in the opposite direction and causing the opposite reciprocation. Reciprocation of the rack 151 causes rotation of the gear 152 meshed therewith, which is in turn united with gear 153 for corresponding rotation, gear 153 is meshed with gear 154 which is united with gear 155 for corresponding rotation, and gear 155 is meshed with the gear sector 150. Thus, through the gear box 156, reciprocation of the rack 151 causes a corresponding reciprocatory rotation of the guide tube 101. In normal operation, the jettisoning mechanism need not be employed. It is brought into operation only when a rocket which has been introduced into the guide tube has failed to fire within a predetermined time. If after closure of gate tube 102 and the lapse of the predetermined time the rocket loaded in the launcher has failed to fire, the feeding and loading mechanisms automatically cease operation; whereupon, the hydraulic piston may be operated to cause reciprocation of rack 151, and thus rotation of the guide tube 101 to bring the opening 101a therein into coincidence with the opening 102a in the gate tube 102, these openings being directed away from the feeding mechanism as shown in FIG. 9, enable the dud rocket to be jettisoned from the launcher either by gravity or by any other suitable means. When the opening of the guide tube 101 has been thus brought into coincidence with the opening of the gate tube 102, the piston has moved so as to bring the limit pin 164 into contact with the switch arm 162 and cause it to be thrown, thus initiating the return stroke of the piston to return the guide tube 101 to its initial position as shown in FIG. 8, with its opening directed toward the feeding mechanism in readiness to resume operation. The automatic cessation of the feeding and loading operations when a dud rocket has thus failed to fire, effectively eliminates the possibility of a jam up at the launcher from this source, and the provision of the jettisoning means provides for resumption of operation in the event that a dud rocket does enter the launching barrel.

The hydraulic piston mentioned hereinabove is shown in detail in FIGS. 17 and 18. When the piston 173 is in the position shown in FIG. 17, the limit switch 161 is in a position which results in high pressure fluid being fed through the line 160 against the pilot piston 168 to move it to the position shown in FIG. 18, and thereby enabling the fluid to pass through the passage 172 and into the chamber 171 to force the hydraulic piston and its associated rod 166 to the left as shown in FIG. 18. The exhaust fiuid from the piston chamber 170 during this movement flows through the passage 169 and thence out through the exhaust pipe 159. When the piston 173 reaches the position shown in FIG. 18, the limit switch 161 is thrown in the opposite position removing the high pressure from inlet and causing the high pressure fluid to be applied solely to the left end of pilot piston 168 as shown in FIGS. 17 and 18 through the inlet line 158 and through the passage 158a formed in the pilot piston to move it to the right to the position shown in FIG. 17, thus enabling the high pressure fluid to pass from inlet 158 through the passage 169 and into chamber 170 to force the piston 173 to the right to the position shown in FIG. 17. The exhaust from chamber 171 flows through the passage 172 and thence out through the exhaust pipe 159. A bleed valve 167 operates in conjunction with the control piston 168 to facilitate movement thereof in its seat which would otherwise be hindered by the entrapment of air or the formation of a vacuum between pilot piston ring 175 and the portion of the pilot piston casing designated by the numeral 176. As indicated above, one complete reciprocatory cycle of this piston results in rotating the guide tube 101 into its jettisoning position, as shown in FIG. 9, and then returning it to its normal operating position, as shown in FIG. 8, after the dud rocket has been jettisoned.

The accomplishment of the foregoing operations will be more fully understood after a consideration of the following sections entitled Electrical Firing and Operational Control System and Hydraulic System.

As indicated earlier in the present specification, a fire and jettison control device is provided, the effects of which are to cause an automatic cessation of the feeding and loading operations if a rocket positioned within the launching tube has failed to fire within a predetermined time, to prevent the firing of a rocket during the jettisoning operation, and to enable the jettisoning operation to be carried out when a dud rocket is positioned in the launching tube. The present is a discussion of this mechanism directed primarily to its mechanical structure and operation, with only incidental references to its operation in conjunction with the firing and operational control circuits, that being reserved for detailed consideration in the section entitled Electrical Firing and Operational Control System.

Referring now to FIGS. 10 and 11, a bumper 280 is positioned in the wall of the launching tube 101 opposite from the rocket loading opening 101a therein, couched between the two rocket bearing rings 603 designed to engage the rear peripheral surface of a rocket, and is shown as having three operative positions, the solid line intermediate position and the two dotted line positions 280a and 280b. The dotted line position 280a is occupied when no rocket is positioned within the launching tube 101, the solid line position is that occupied when a rocket is positioned within the launching tube, and the dotted line position 28011 is that occupied upon the firing of a rocket as it passes out of the tube. When a rocket is positioned within the launching tube, the bumper 280 is forced into the solid line position by engagement thereof by the groove 80 about the rockets circumference.

Bumper 280 is linked by means of the connecting pin 290 to the bell crank 281, rocking about its pivot pin 282. A rod 283 is connected to the rocking arm 281 by means of the bolt 291 and is substantially enclosed within a housing comprising the housing elements 295, 285, 284, and 284a and the adjustment nut 296. A spring 292 bears between the elements 284 and 284a, and a second spring 286 preferably of the fiat washer construction indicated bears between the elements 284a and 295. Movement of the bumper from the position 280a toward the position 280b causes a movement of arm 281 to compress the springs 292 and 286, the housing elements 284 and 284a being separable and reciprocable within a portion of the element 285. The return movement of bumper 280 from the position 280b toward the position 280a is obtained when the launching tube is empty in response to the compressed springs 292 and 286. Spring 286 controls the movement of bell crank 281 between the solid line position of bumper 280 and its dotted line position 280a, while spring 292 controls the action between the solid line position and dotted line position 28% of bumper 280, the desired initial compression of spring 292 being obtained by the adjustment of nut 296 on the rod 283. In addition, arm 281 carries two contact lugs 287 and 287a, only the former of which is shown in the longitudinal sectional view of FIG. engaging the contact plate 288, both lugs being shown in FIGS. 20, 21, and 22. The contact lug 287 is held in position by the bolt 297 against the compression of spring 289 contained within the insulated housing 298. The mechanical structure of lug 287a is substantially identical to that shown for lug 287.

Thus, with the launching tube 101 empty, the bumper 280 assumes the dotted line position 280a as forced there by the action of springs 292 and 286 upon the rocking arm 281. In this position the contact lug 287 is out of engagement with the contact plate 288. When a rocket is introduced into the launching tube 101, the bumper 280 is forced into the solid line position by engagement therewith of slot 80 on the rocket casing, resulting in a commensurate movement of rocking arm 281 against the spring 292, thereby causing the contact lug 287 to engage the contact plate 288. Upon firing of the rocket, as it moves past the bumper 280 the latter is forced into the dotted line position 280b, causing a commensurate movement of the rocking arm 281 against the spring 286. In this position, a greater pressure is exerted by the contact lug 287 upon the contact plate 288 causing a relative movement between the lug and the housing 298 against the spring 289.

The purpose of the present mechanism is to control the engagement between the contact lugs 287 and 28711 and the contact plates 288, 288a, and 299, see FIGS. 20, 21, and 22, thus operating as a control switch in the firing and the jettisoning control circuits. These control operations will become apparent from a consideration of the detailed discussions of the electrical firing and operational control system, the present discussion being limited primarily to a consideration of the mechanical operation of this fire and jettison control mechanism. FIG. 21 shows the launcher in open position ready to receive a rocket yet still empty, therefore no pressure is exerted against the bumper 280 and the contact points 287 and 287a are held out of engagement with the plates 288 and 288a respectively; FIG. shows the launcher in a loaded condition with a rocket pressing against the bumper 280 causing the contact lugs 287 and 287a to engage their respective plates 288 and 288a; and FIG. 22 shows the jettisoning position of the launching tube with the rocket already jettisoned therefrom, yet due to the rise 299a connecting the contact plates 288 and 299, the contact lugs are maintained in engagement therewith despite the empty condition of the launching tube and the fact that the bumper 280 has assumed the dotted line position 280a shown in FIG. 10. The contact lugs 287 and 287a, being united to the launching tube 101 through rocking arm 281, move in correspondence therewith to transverse the contact plate 288a, and plate portions 288, 299, and the rise 299a between portions 288 and 299, the two contact plates being fixed in position by attachment to the structural frame of the rocket launcher, or to any other convenient stationary portion thereof. The reason for the rise 299a for maintaining engagement between contact plate portion 299 and the contact lugs after jettisoning of the rocket will become apparent from the subsequent discussion of the electrical firing and operational control circuit.

As indicated in the previous discussions of the loading and jettisoning operations and of the launcher mechanism, the guide tube and gate tube are each independent- 1y rotatable. The following is a description of one means which may be employed for mounting the guide tube on the structural frame of the present rocket launcher and for mounting the gate tube on the guide tube to enable the desired rotational movements, and is made with particular reference to FIGS. 10 and 13. Of these two mountings, considering first that of the guide tube 101 reference will be had primarily to FIGS. 10 and 13, FIG. 13 being a cross-sectional view of the launching barrel taken along the line 13-13 of FIG. 10 and showing a cross-sectional view of the rear mounting of the guide tube. The rear guide tube mounting comprises a bearing annulus 200, attached to the guide tube for rotation therewith, and the mounting sleeve 201, fixed to the structural frame of the present rocket launcher and carrying therein the guide tube and its bearing annulus. As shown particularly in FIG. 10, the bearing annulus 200 is bolted or otherwise securely afiixed to the guide tube 101 and has extending therefrom an eccentric bearing plate portion indicated by the numeral 215. As can be seen by reference to FIG. 13, the bearing plate portion 215 is free to rotate within the mounting sleeve 201 whose internal diameter is slightly larger than the external diameter of the eccentric bearing plate 215. In addition, the mounting sleeve 201 is provided at its forward end with the inwardly projecting shoulder 214 throughout its circumference for engaging the leading edge of the bearing plate portion of the annulus 200, while the leading edge of the annulus 200 is provided with the projecting flange or key 600 over a portion of its outer circumference engaging the groove or keyway 601 formed over a portion of the inner circumference of the mounting sleeve 201, thereby preventing longitudinal slippage of the guide tube through the mounting and guiding the rotational movement of the tube therein.

As indicated above, the mounting sleeve 201 is fixed in position and supported by the structural frame of the rocket launcher. As shown in FIG. 13, this is accomplished through three of the transverse structural frame supports 30 and two vertical supporting beams 202 and 20211, which are preferably as shown in the drawings U-shaped channel beams. The bottom support for the mounting sleeve 201 comprises two of the transverse frame structural beams 30 connected by the bridge member 700, which is so formed as to conform to the exterior contour of the bottom portion of the mounting sleeve 201. The beams 202 and 202a are supported between the top and bottom structural beams 30, shown in FIG. 13. These beams are each formed along one side to conform to the exterior contour of the side portions of the mounting sleeve 201 and thereby each provide a side support therefor. Thus, there is alforded substantially a three point suspension for the cylindrical mounting sleeve.

With the structural support thus formed by the beams 30 and the vertical struts or beams 202 and 202a, the annular mounting sleeve 201 is welded or otherwise fixed in position thereto. The guide tube 101 is then inserted through the mounting sleeve 201, the bearing annulus 200 is slipped over the tube and positioned thereon with its forward edge in engagement with the shoulder 214 of the sleeve 201, the bearing annulus is bolted or otherwise aflixed to the tube, and the tube and annulus are then rotated to bring key 600 into its keyway 601. Having thus described the rear mounting of the launching tube, it is sufficient to mention that as indicated in FIG. 2 an identical mounting structure is provided at the forward end of the guide tube, but having the shoulder 214 of the mounting sleeve 201 cooperating with the rear edge of the bearing annulus 200; these two mounting structures thus cooperate with each other to prevent longitudinal slippage of the guide tube in either direction, yet permit rotation thereof.

As previously indicated, the gate tube 102 is carried by the guide tube 101 and is mounted for rotational movement thereon. In describing this carriage, reference will be had particularly to the longitudinal section of the rear end of the launching barrel shown in FIG. 10. A plurality of brackets 219 are secured to the guide tube 101, each carrying a roller contact wheel 220, while the gate tube 102 is provided with the grooved trackway 221 for the roller contacts 220' secured to the end of the main body thereof by riveting, welding, or the like. Thus, the gate tube 102 may be slid into position over the guide tube 101 and the brackets 219 bolted into position upon the guide tube 101 to bring the roller contact wheels into engagement with the groove 221. The forward end of the gate tube is similarly constructed and cooperates with a similar group of brackets and roller contact wheels, thereby providing for rotation of the gate tube about the guide tube as required by the above-described loading operation. Thus, the above-described mounting for the guide tube and the mounting of the gate tube over the guide tube provide for independent relative rotation between said two tubes for accomplishing the desired operational functions of the rocket launcher. As is apparent, the gate tube is mounted on the guide tube before the latter is positioned on its mounting structures as described above, when the specific mounting structure here described is employed. A bulfer mechanism 203 is associated with each of the two launching tube supporting structures described above, one of which is shown in its operative position in FIGS. and 13, and is shown separately in detail in FIGS. 14 and 15. Referring to these drawings, the butter mechanism includes a casing 217 within which is contained a hydraulic system enclosed between the two pistons 262 and 254, the piston 262 operating against the coil spring 263 and the piston 254 engaging the bearing surfaces 215 of the bearing annulus 200 through its roller contact wheel 216. The buffer mechanism is seated in position by means of the two extending plates 251, formed as an integral part of the casing 217, which are clamped to the vertical strut 202a by bolts 252, or the like. The roller contact wheel 216 and the wheel carrying extending arm 253 of the piston 254 pass through suitable opening in the strut 202a and the mounting sleeve 201 to enable the roller contact 216 to engage the bearing surface 215 of the bearing annulus 200, forcing the launching tube and its associated annulus 200 into bearing engagement with the opposite portion of the sleeve 201. The extension 253 of the piston 254 is reciprocably mounted in the bushing 254a threaded into the casing 217, and is there held against rotation by the pin 256 extending across the bushing 254a and passing through the elongated slot 255 in the extension arm, while the piston 254 is contained within the seat 258. At the other end of the hydraulic system another piston 262 is positioned in the seat 261 and operates in conjunction with the helical spring 263 positioned in the chamber 264. The chamber 261a delineated by the piston 262 is connected through passage 259 to the chamber 258a delineated by the piston 254. Thus, when pressure is exerted upon the roller contact 216 so as to exceed the force exerted by the spring 263, the piston 254 moves inwardly Within its seat causing the fluid in chamber 258a to pass through passageway 259 and into the chamber 261a to force the piston 262 upwardly into the chamber 264 against the compression of the helical spring 263. Upon release of the pressure applied to the wheel 216, the fluid thus contained in the chamber 2611;; against the pressure of the spring 263 may return through the passageway 259 into the chamber 258:: to force the piston 254 into its starting position as shown in FIG. 14. However, the passageway 259 is provided with an adjustable cock 260, shown in detail in FIG. 15, which acts as a How check for the fluid passing through the passageway 259. Thus, if the cock 260 is so positioned as to substantially constrict the passage 259, the hydraulic buffer mechanism responds slowly to pressure applied to the contact wheel 216 to cushion more effectively large shocks received by the piston arm 253, and the return of fluid through the passageway 259 into the chamber 258a would be correspondingly sluggish and cause a slow return of the piston 254 to starting position, thereby increasing the time interval before the mechanism is in readiness to receive a subsequent shock; therefore, a return passage 267 is provided from the chamber 261a to the chamber 258a passing through the one way ball valve 268, spring pressed in its seat by means of the spring 269, this return line being completed through the passageway 270 into the chamber 258a. Thus, when the cock 260 is turned for slow action of the buffer mechanism and shock pressure is applied to the contact wheel 216, the piston 254 yields thereto and operates against the piston 262 and its spring 263; but upon release of the pressure applied to arm 253, the return of the buffer mechanism to starting position is substantially instantaneous as effected by the ready return of fluid through the return line. A buffer mechanism identical to that here described is correspondingly positioned upon the supporting structure carrying the forward end of the guide tube, as indicated in FIG. 2.

Thus, with the present buffer mechanisms in place upon the supporting structures of the guide tube and with their contact wheels 216 in engagement with the bearing surfaces of the annuluses 200, shocks imparted to the guide tube by the introduction of rockets thereto from the feeding mechanism, as accomplished by the aforedescribed accelerated movement of the last star wheels, are substantially absorbed by the buffer mechanism, thereby protecting the supporting structure of the rocket launcher from the strains which would otherwise result therefrom; for as a rocket is introduced into the launch ing tube, the shock imparted thereto causes the tube and its bearing annuluses to move against the contact wheels 216 and the piston arm 253, resulting in a substantial absorption of the shock by the two buffer mechanisms as above-described. Variations in the adjustment of the cocks 260 enable effective buffering of various shock loads.

In the launching of rockets a relatively large blast of hot and usually noxious gases is produced. It is desirable, therefore, that such an exhaust blast be directed away from the operators of the launching mechanism and be deflected from the structure upon which the rocket launcher is mounted. To this end the present rocket launcher is supplied with a blast deflector 204, which may be so turned as to funnel the exhaust gases in a direction away from the operator and the structure upon which the rocket launcher is mounted.

For the previously described operations of the present rocket launcher, the guide tube 101 is rotatably mounted upon the structural frame of the present device. Since the exhaust end of the guide tube must be connected to the blast deflector for the same to be effective, and since it is preferable that the blast deflector be stationary to minimize the load on the guide tube rotational power source and strains on the supporting structure, special provision must be made for effecting a coupling therebetween. One embodiment of a suitable coupling is shown in FIG. 10, wherein two intermediate coupling elements 207 and 210 are provided to form a rotational and substantially gas tight union between the blast deflector 204 and the exhaust end of the launching tube 101. The coupling element 210 is an annular member circumscribing the exhaust end of the guide tube 101 and is securely aflixed thereto by means of bolts, rivets, or the like through the portion 212 thereof, while the portion 211 forms an extending flange about the exhaust end of the guide tube 101. The exhaust deflector 204 is united by its flange 205 to the flange 206 of the coupling element 207, while this coupling element is formed with the second flange portion 223 engaging the flange portion 211 of the coupling element 210. A third flange portion 224 is formed on the coupling element 207 which is securely united to the structural frame of the rocket 

